RU2673974C2 - Long-life heat recovery steam generator device with use of internal stiffeners - Google Patents

Abstract

FIELD: machine building.SUBSTANCE: present invention relates to heat recovery steam generators, to laying a channel system associated with such devices. Heat recovery steam generator comprises a plurality of modules including a corresponding upper annular flange and a corresponding lower annular flange. Each of the modules is connected to at least one other module for jointly defining a housing having a first side, a second side, a third side and a fourth side, defining therebetween an inner part of the housing and an outer part of the housing. Inner part of the housing defines at least one channel for the flow of heated gas along the flow axis of the heated gas. Each channel includes a plurality of channel elements that are spaced apart from each other along the flow axis of the heated gas to limit the gaps between them. Channel elements extend from the first side to the fourth side inside the inner part of the first housing and are located at a distance from the second and third sides. Plurality of stiffeners extending along the axis of flow of heated gas, wherein each of the stiffeners is located on the first wall and the fourth wall in the inner part of the housing and is located between two of the channel elements. Stiffeners and channel elements almost have the same coefficient of thermal expansion. Upper annular flange of each module is attached to the corresponding upper ends of the channel elements and the corresponding upper ends of the stiffeners. Lower annular flange of each module can be attached to the corresponding lower ends of the channel elements and the corresponding lower ends of the stiffeners. Plurality of connecting rods, each of the connecting rods is connected to at least one of the channel elements and one of the lower annular flange and the upper annular flange. Connecting rods are pulled outside the first housing only on the first and second sides of the housing to be attached to structural steel, wherein outside the first housing on the third and fourth sides of the housing, the connecting rods are not pulled to attach to structural steel. In yet another embodiment of the invention, the heat recovery steam generator comprises a shell having an outer part, comprising a top and a bottom opposite the top, and the top defines top opening, and the bottom defines a bottom opening, wherein the outer part also has a first side, a second side, a third side and a fourth side.EFFECT: reducing the cracking of the structure and reducing structural distortions and deformations in the heat recovery steam generator.16 cl, 4 dwg

Description

FIELD OF THE INVENTION

[0001] The present disclosure relates to steam generators-recuperators, to laying a channel system associated with such devices.

State of the art

[0002] Power plants may employ gas turbines with steam generator-recuperators (HRSGs), which can use thermal energy in exhaust turbines to generate steam for generating electricity or a process. Examples of HRSG and the use of HRSG are given in the publication of patent applications (USA) No. 2013/0180228, 2013/0180696, 2012/0240871 and 2011/0048010 and in patents (USA) No. 7353654, 6957630 and 5924389. HRSG can operate at very high temperatures in normal steady state operation, and the HRSG inlet region can operate at a temperature that is significantly higher than the temperature of the fluid flowing from the HRSG outlet. Additionally, often there are significant differences in temperature within HRSG compared to ambient temperature outside HRSG.

[0003] The modern technology used for HRSGs with a heated case often has problems after one to two years of operation. For example, HRSGs with a heated housing use external hardening structures that are susceptible to damage between stiffeners and the inlet housing or the main HRSG housing. Examples of such damage may include cracking of certain structures. Deformation or curvature can also occur between the housing and other external elements, for example, external stiffeners. The diagonal extension can also be deformed or cracked at the location where the diagonal extension is attached to the HRSG wall. In addition, housing connections between adjacent walls of the HRSG may crack, allowing hot gas to flow into the atmosphere within the HRSG. To solve such problems, HRSG often need to stop for repairs within the first few years of service.

SUMMARY OF THE INVENTION

[0004] According to aspects illustrated herein, an HRSG is provided comprising a first housing having an interior housing at least one first gas flow passage along an axis of the gas flow. Each first channel is defined by channel setting elements, which are spaced from each other and enter the inner part of the first housing. A plurality of stiffeners elongated along the axis of the gas flow is also included in the first housing. Each of the stiffening elements is located in the inner part and is placed between two of the channel defining elements. The stiffening elements and channel setting elements have almost the same coefficient of thermal expansion.

[0005] According to other aspects illustrated herein, a vertical HRSG component comprises a first module having a first housing accommodating at least one first channel for passing gas through it along a gas flow axis. The first housing includes the elements of the job of the first channel and many of the first stiffeners. Each first channel is defined by spaced job elements of the first channel extending within the housing. The first stiffeners are placed between the spaced elements of the job of the first channel. The first stiffeners are elongated along the axis of the gas flow. The first stiffening elements and the elements of the task of the first channel have almost the same coefficient of thermal expansion.

[0006] According to other aspects illustrated herein, a vertical HRSG comprises a shell having an outer portion including a top and a bottom opposite the top, the top defining an upper hole and the bottom defining a lower hole. The outer part also has a first side, a second side, a third side and a fourth side. The first side extends from top to bottom and is placed between the second side and the third side. The second side extends from top to bottom and is placed between the first side and the fourth side. The third side extends from top to bottom and is placed between the first side and the fourth side. The fourth side extends from top to bottom and is positioned between the second side and the third side so that the fourth side faces the first side and the second side faces the third side. Many channel assignment elements extend within the envelope. The channel defining elements extend within the shell and define at least one channel defined within the shell for gas to pass through at least one channel along the gas flow axis extending from the bottom of the shell to the top of the shell. Many internal stiffeners are within the shell. Each of the internal stiffeners is elongated along the axis of the gas flow and is placed between two of the channel defining elements. Internal stiffeners and channel defining elements have almost the same coefficient of thermal expansion.

[0007] The above and other features are illustrated by the following drawings and detailed description.

Brief Description of the Drawings

[0008] Referring now to the drawings, which are exemplary embodiments of implementation and in which like elements have like numbers:

[0009] FIG. 1 is a perspective view of a first exemplary embodiment of an HRSG. It will be appreciated that structural steel that can be positioned at least in part along the perimeter of the HRSG to support the HRSG is not shown in FIG. one.

[0010] FIG. 2 is a perspective view of a first exemplary embodiment of an HRSG in a first stage of completing an HRSG design.

[0011] FIG. 3 is a partial top view of a first exemplary embodiment of an HRSG with sections of HRSG in section to illustrate stiffening elements and HRSG channel setting elements.

[0012] FIG. 4 is a partial perspective view of a first exemplary embodiment of an HRSG with sections of HRSG in section to illustrate stiffening elements and HRSG channel setting elements.

[0013] Other details, objects, and advantages of the innovations disclosed herein should become apparent from the following description of exemplary embodiments and associated exemplary methods.

DETAILED DESCRIPTION OF THE INVENTION

[0014] A steam recuperator (HRSG) is disclosed herein that is configured in such a way that the temperature difference of the metal and the resulting relative thermal expansion of the HRSG elements are taken into account and minimized in its design and construction. This is the exact opposite of the modern traditional considerations used in the design and creation of HRSG. For example, modern design principles say that mechanical stresses caused by the temperature difference of the metal and the resulting relative thermal expansion experienced by plates, external stiffeners or other elements of the HRSG channel can be ignored, and mechanical stresses that can result from temperature changes, caused by thermal conditions within the HRSG, therefore, are traditionally ignored in the design and manufacture of HRSG. Despite this traditional principle today, due to significant inventive efforts it has been determined that mechanical stresses that can result from temperature changes should not be ignored in the design and manufacture of HRSG. The thermal stress drop can be taken into account in the design and manufacture of the HRSG, and the HRSG can be configured in such a way that it can satisfy the mechanical stresses that can result from temperature drops within the HRSG. The choice of design solutions, taking into account the mechanical stresses that can be caused by the heat differential mode within the HRSG, can allow HRSG to have a duty cycle that is many times longer than traditional HRSG designs. For example, in some HRSG embodiments, a duty cycle is assumed that is many times longer than traditional HRSG constructs.

[0015] Referring to an exemplary embodiment of a vertical HRSG 100 illustrated in FIG. 1-4, the HRSG may include a first housing 100a, which may also be considered a main housing, which is located between the inlet channel 100b and the outlet channel 100c. The HRSG embodiment shown in FIG. 1-4 can be configured as an HRSG with a heating case using internal stiffeners, and the first case 100a can be configured as a heating case using internal stiffeners. Embodiments of long-life HRSGs using internal stiffeners may be referred to as “ISES HRSGs” hereinafter.

[0016] The exhaust duct 100c may be considered a chimney in some embodiments of the ISES HRSG. Heated gas from the turbine can be received at the ISES HRSG through the inlet 100b. The heated gas can pass through the inlet to the first housing 100a and can be released from the ISES HRSG and into the atmosphere through the outlet of the outlet channel 100c. The inlet channel 100b may be operatively connected to an outlet of a turbine, such as an internal combustion turbine, or to another plant unit that can produce hot gas. One or more pipelines may connect the inlet 100b to a turbine or one or more plant nodes that can supply hot gas to the ISES HRSG. Hot gas received through the ISES HRSG inlet 100b can have a relatively high temperature, for example, 500-600 ° C and can be released from the ISES HRSG outlet at a lower temperature, for example, 100-200 ° C. For example, hot gas can be received in the inlet 100b at 550 ° C, 575 ° C or 600 ° C and released from the outlet 100c into the atmosphere (for example, into air external to the ISES HRSG or ISES HRSG) at a temperature of 150 ° C, 175 ° C or 200 ° C. Alternatively, the gas emitted from the ISES HRSG outlet 100c may be supplied to another device (not shown) for subsequent processing or to use the emitted gas instead of being released to the atmosphere.

[0017] ISES HRSG 100 may be configured in such a way that ISES HRSG includes a first housing having a shell that has an inside accommodating at least one first channel for gas to flow along gas flow axis 102. The gas flow axis 102 may be a vertical axis that extends along the Y axis so that gas can flow vertically through one or more of the first channels 305 from the lower ISES HRSG section to the upper ISES HRSG section, which is located above the lower section. It will be appreciated that the X x axis, Y y axis, and Z z axis, identified in FIG. 1-4 may have a configuration in which the Y axis can specify a vertical direction of height, the Z axis can specify a direction of depth, and the X axis can specify a direction of length.

[0018] As best understood from FIG. 2, the first housing 100a may consist of a plurality of modules that are coupled to form the first housing 100a. Each module 400 may have a box shape, for example, a structure having top, bottom, and first, second, third, and fourth sides extending from top to bottom such that the first side is located between the second and third sides and faces the fourth side. The top and bottom of each module can be generally open, so that gas is flowing from one module to another module of the first housing 100a. In this regard, the top and bottom of each module may have an upper surface that has a generally annular shape, and a lower surface that has a generally annular shape.

[0019] As best understood from FIG. 3-4, a plurality of connected modules 400 may define an array of connected flanges 205, channel defining elements 201, and stiffening elements 203 that are internal to the shell of the first HRSG body 100a and that have the same effect or almost the same effect (e.g., influence within a range +/- 5% relative to each other) thermal expansion that can result from hot gas passing through one or more ISES HRSG channels 305 by expansion due to heating of this gas. The channel defining elements 201 have internally extending parts 201a that can extend from one inner side of the housing to the other inner side of the housing, so as to connect the side walls of the housing under compressive loads, and to transfer wind and seismic loads to the connecting rods 207, which serves to in order to effectively transfer such loads to structural steel, to which the connecting rods 207 are attached.

[0020] Each module can be defined by means of the upper flange 205 and the lower flange 205. The modules can be interconnected so that the lower flange of one module can be attached to the upper flange of the module, which is located directly below this module. The upper flange of the module can be attached to the lower flange of the module, which is located directly above this module. It should be appreciated that directly adjacent modules can be modules that are directly in contact with each other or are directly adjacent to each other without placing another module between these directly adjacent modules. The sides of the module, which are directly adjacent to each other, may have edges that are in direct contact with each other, or may be placed in such a way that there are no other sides between these directly adjacent sides.

[0021] ISES HRSG may be configured to have only one first channel 305 through which hot gas passes, or may have several first channels 305 through which hot gas passes. Each first channel 305 can be defined by channel setting elements 201, which are spaced apart from one another and enter the interior of the first housing. A plurality of stiffeners 203 that are elongated along the gas flow axis 102 may also be included in the first housing. Each of the stiffening elements 203 can be placed in the inner part of the shell defined by the first body, and can be placed between two of the channel setting elements 201 next to the first channel 305 defined by at least these two channel setting elements 201. The stiffening elements and channel setting elements may consist of materials having practically similar coefficients of thermal expansion. For example, the coefficient of thermal expansion of the material of which the channel defining elements 201 (for example, a particular grade or type of steel or other metal) are composed can be identical or within 5% of the coefficient of thermal expansion of the material of which the stiffening elements 203 (for example, a specific grade or type of steel, alloy or other type of metal). As another example, stiffeners and channel defining elements may consist of materials having substantially similar thermal expansion coefficients when the coefficient of thermal expansion of the material of which the channel defining elements 201 (for example, a particular grade or type of steel or other metal) is different between 0.5% and 3.0% of the coefficient of thermal expansion for the material of which the stiffening elements 203 consist (for example, a particular grade or type of steel, alloy, or other type of metal). Channel assignment elements having a thermal expansion coefficient that is between 90% and 110% of the thermal expansion coefficient of the stiffening elements 203 are another other example of substantially similar values of the thermal expansion coefficients.

[0022] In some embodiments, the stiffeners can be located exclusively in the inner shell of the first housing, and the first housing can be configured in such a way that the stiffeners and channel defining elements are all that is required to support and define one or more of the first channels 305 defined in the shell of the first housing. Unlike traditional HRSG designs, which often use diagonal braces, ISES HRSG embodiments may have a configuration in which diagonal braces are not included in one or more of the first channels 305. Stiffeners 203 can be placed along the perimeter of the first channels 305 between the elements 201 channel assignments. The stiffening elements 203 may be plates, beams, rods, rods, or other structures that are composed of metal. The channel defining elements 201 can also consist of metal and can be tubular sheets, plates, elements or other structures that are made of metal and enter the inner part of the first casing so that at least partially one or more channels can be defined within the enclosure. The metal of the stiffening elements 201 may have a coefficient of thermal expansion, which is almost the same as the coefficient of thermal expansion of the metal from which the channel defining elements 201 are formed (for example, the coefficient of thermal expansion can be identical or within 5%). The channel definition elements 201 can be configured to define holes 211, gaps or other types of apertures within the body of the channel definition elements 201. The holes 211 can be configured to help simplify the required gas flow through the channels or the required heat transfer from the gas flowing within the channels specified by the channel setting elements 201. The channel defining elements 201 may also have other apertures formed by drilling or other aperture shaping mechanisms to allow the structure to pass through the ISES HRSG channels. For example, holes can be drilled into channel defining elements 201 that are sized to receive a pipe system for a heat exchanger that can extend through ISES HRSG channels so that the heat exchanger can be used to transfer heat from gas passing through the ISES HRSG to the fluid medium within the tubes of the heat exchanger. An example of such a heat exchanger may be an evaporator that evaporates water into steam using heat from a gas passing through the ISES HRSG to supply such steam to the steam drum of a power generation plant or for other industrial uses of steam.

[0023] The holes formed in the various channel setting elements can be arranged so that the holes of the various channel setting elements are aligned so that the tubes can extend horizontally through the ISES HRSG channels and extend from one side to the opposite side of the ISES HRSG. Each channel defining element may have a plurality of formed openings that are vertically spaced apart from each other to allow a plurality of rows of vertically spaced sets of heat exchanger pipelines to pass through the HRSG to transfer heat from the gas passing through the ISES HRSG to the fluid within the pipelines. For example, the channel defining element 201 may have at least three formed holes that are spaced apart from each other along the length or height of the channel defining element so that the first hole is located between the upper hole and the lower hole. Holes 211 can also be defined within the channel definition elements to align the holes 211 or otherwise arrange the matrix of holes 211 within the channel definition elements 201 to simplify the desired gas flow or heat transfer profile within the ISES HRSG channels.

[0024] Each of the flanges 205 may extend around all of at least one channel defined by the channel defining elements of the module 400, and each of the upper and lower flanges 205 of the module 400 may be internal flanges that are attached to a plurality of elements 201 channel assignment, a plurality of internal stiffening elements 203, and a plurality of connecting rods 207 that extend from a module 400 to attach to structural steel that can be placed adjacent to the ISES HRSG. Each inner flange 205 may consist of elongated plates, beams, or other elements that are interconnected to define an annular structure. The connected elements of each inner flange 205 can be fixed to each other through fasteners, welding, or other connecting mechanisms to define the ring structure of the inner flange 205. The inner flanges 205 can be formed from a material having a thermal expansion coefficient that is almost the same as the thermal expansion coefficient of the job elements channel (for example, the coefficient of thermal expansion of the inner flanges 205 is identical or differs by +/- 5% from the coefficient of thermal expansion for stiffening elements 203, and is also identical or differs by +/- 5% from the thermal expansion coefficient of channel setting elements 201).

[0025] Each of the connecting rods 207 can be connected to at least one of the channel defining elements 201 and one of the lower inner annular flange and the upper inner annular flange of the module 400. The connecting rods 207 can extend only two directly outside the first housing adjacent sides of the first housing for connection to structural steel next to two directly adjacent sides of the first housing. For example, connecting rods 207 may extend from a location near the rear and left side of the first housing to attach to structural steel near these sides. As another example, the connecting rods 207 can extend only from the front and left sides of the first housing to join structural steel adjacent to these sides of the first housing. As yet another example, the connecting rods 207 can extend only from the rear and right sides of the first housing to join structural steel next to these sides. Structural steel to which the connecting rods 207 are attached can be significantly colder than the temperature of the heated gas passing through one or more of the ISES HRSG channels, the temperature of the internal channel defining elements 201, and the temperature of the internal stiffening elements 203. For example, structural steel may have an ambient temperature that is identical or, in general, identical to the temperature of the environment in the area where the ISES HRSG is located, while the temperature of the heated gas passing through the ISES HRSG and flanges 205, elements 203 stiffness and channel setting elements 201, can vary from 150 ° C to 550 ° C.

[0026] Insulation can be placed between modules 400 and structural steel to help retain heat within one or more HRSG channels 305, so that this heat can be used efficiently. Coupling rods 207 may extend through an insulation layer interposed between a shell defining one or more channels 305 and an external frame that includes structural steel supports to support the ISES HRSG.

[0027] When the connecting rods 207 are pulled only from two directly adjacent sides of the ISES HRSG to connect to structural steel next to the two sides, the other sides of the ISES HRSG are allowed to expand under thermal stresses, which can lead to a significant reduction in thermal stresses experienced by ISES HRSG, which follows from the expansion of ISES HRSG elements due to thermal conditions within ISES HRSG. Reducing the thermal stresses achieved by the ISES HRSG embodiments allows ISES HRSG components, such as internal flanges, internal stiffeners, and internal channel elements, to support ISES HRSG loads without using diagonal braces or supports provided by external stiffeners.

[0028] Each module 400 of the first housing 100a may be considered a component of the vertical ISES HRSG. Each module 400 may include a first housing accommodating at least one first channel 305 for passing gas through it along the axis 102 of the gas stream. The first housing of the module 400 may include elements of the job of the first channel. Each first channel 305 may be defined by spaced-apart job elements of the first channel 201, which extend within the housing. Many of the first stiffening elements 203 are also located between the spaced apart elements of the job of the first channel 201 and are elongated along the axis 102 of the gas flow. For example, stiffeners may be elongated vertically. The first stiffeners and the elements of the task of the first channel can have almost the same coefficient of thermal expansion (for example, the coefficient of thermal expansion of the elements 201 of the channel can differ by +/- 10% or +/- 5% from the coefficient of thermal expansion of the elements 203 of the stiffness). Each module 400 may have a configuration in which there are no diagonal braces that are included in at least one first channel 305.

[0029] Each module 400 may include an upper annular flange 205 and a lower annular flange 205. The upper annular flange can be attached to the upper ends of the first channel specifying members of this first module and the upper ends of the first stiffening elements of the first module. The lower annular flange can be attached to the lower ends of the elements of the job of the first channel and the lower ends of the first stiffeners. Each module 400 may also include a plurality of connecting rods 207 for connecting to structural steel, which should be located next to the module 400. Each of the connecting rods can be connected to one of the elements of the first channel 201 and one of the lower annular flange 205 and the upper annular flange 205.

[0030] Each module may have a housing that includes an upper annular surface that defines the upper hole, a lower annular surface that defines the lower hole, the first side between the upper surface and the lower surface, the second side between the upper surface and the lower surface, the third the side between the upper surface and the lower surface and the fourth side between the upper surface and the lower surface. The connecting rods 207 can only extend from the first and second sides of the first housing, so as to limit the expansion of the first and second sides of the first housing, so that the expansion of the first housing, caused by thermal conditions with the first module, should lead to a significant expansion of the first housing through freedom to expand the third and fourth sides of the first building.

[0031] From FIG. 1-4, it can be appreciated that the ISES HRSG embodiment may be a vertical ISES HRSG, which has a shell having an outer portion containing an upper and a lower opposite the top and the first side, the second side, the third side and the fourth side. The first side may extend from top to bottom and be placed between the second side and the third side. The second side can be extended from top to bottom and placed between the first side and the fourth side. The third side can be extended from top to bottom and placed between the first side and the fourth side. The fourth side can be extended from top to bottom and placed between the second side and the third side so that the fourth side faces the first side and the second side faces the third side. A plurality of channel defining elements 201 may extend within the envelope. The channel defining elements 201 can extend within the envelope and define at least one channel defined within the envelope for gas to pass through at least one channel along the axis 102 of the gas flow extending from the bottom of the envelope to the top of the envelope. A plurality of internal stiffening elements 203 may be placed within the shell. Each of the internal stiffening elements 203 is elongated along the gas flow axis 102 and is located between two of the channel setting elements 201. The internal stiffening elements and channel setting elements have a practically similar coefficient of thermal expansion (for example, the thermal expansion coefficient of channel setting elements 201 may differ by +/- 10% or 5% from the thermal expansion coefficient of stiffening elements 203).

[0032] Each of the plurality of connecting rods 207 may be attached to and extended from one of the channel defining elements 201 to extend from one of the first side of the shell and the second side of the shell to attach to structural steel adjacent to the first and second sides of the shell. The connecting rods 207 can extend only from the first and second sides of the shell, so that the expansion of the shell caused by thermal conditions within the shell should lead to a significant expansion of the shell through the expansion of the third and fourth sides of the shell, which are not limited through the connecting rods 207 and structural steel to which these connecting rods 207 are attached. The connecting rods 207 may be configured to be connected to the first and second supports 301 and 303 of structural steel near the first and second sides of the shell, so that the expansion of the shell caused by thermal conditions within the shell should only lead to the expansion of the third and fourth sides of the shell.

[0033] In some embodiments, the modules 400 may be connected so that the lowest module 400 is connected to the inlet channel 100b and the upper module 400 is connected to the ISES HRSG outlet channel 100c. The uppermost module 400 may have an upper flange that is connected to the upper supports 209 that connect the uppermost module to steel beams 403, which are supported by steel supports 405. The upper supports 209 may be flanged rafters that are supported by wide-flange struts, or other types of steel beams 403 and steel supports 405 of the ISES HRSG frame. Other designs may also be attached to steel beams 403 and supports 405 and may define an external casing or frame for HRSG. The first and second structural steel supports 301 and 303 can be placed on two directly adjacent sides of the ISES HSRG and configured to support the ISES HRSG and help the ISES HRSG to maintain a vertical position. The first and second structural steel supports 301 and 303 may be parts of an external frame that support the ISES HRSG, or may be separate steel structures that are external to the ISES HRSG and are located adjacent to the external sides of the HRSG. The first and second structural steel supports 301 and 303 can be attached to the base of the production site.

[0034] The connecting rods 207 may extend from the modules 400 into these first and second structural steel supports 301 and 303. The connecting rods 207 can be attached to different flanges of the modules, so that the connecting rods 207 have a predetermined spacing. For example, the first row of connecting rods 207 can be attached to the lower flange 205 of the lower module, and the second row of connecting rods 207 directly above the first row of connecting rods can be attached to the upper flange of the module placed directly above the lower module, so that a distance equal to the height of two modules, carries the lower first row from the upper second row. The connecting rods 207 of the second row of connecting rods can be connected with both the upper flange of the lower module and the lower flange of the upper module, as well as with the elements of the channel of the lower and upper module. Each of the connecting rods 207 can be connected to the flanges 205 near the place where the connecting rod 207 is connected to the channel defining elements of the upper and lower modules. Additional modules can be connected in a matrix using identical spacing of connecting rods to connect directly adjacent modules and channel defining elements of these modules to the flanges. For example, the matrix of modules can be connected so that the third row of connecting rods 207 is located above the second row of connecting rods and is also spaced from the second row to the height of two modules.

[0035] In yet other embodiments, the matrix of connecting rods 207 and modules 400 may be configured differently. For example, the connecting rods 207 can be attached to each flange 205 of each module, as well as to the channel defining elements 201 of these modules to which this connecting rod is connected. Each connecting rod 207 may be coupled to at least one corresponding channel defining element 201 and corresponding to one of the flanges in such embodiments.

[0036] The connecting rods 207 may be configured to attach to structural steel adjacent to two directly adjacent sides of the first housing 100a. For example, the rear and left side of the housing or the rear and right side of the housing may have connecting rods 207 extending from them to attach to the first and second supports 301 and 303 of structural steel. Only these two directly adjacent sides can have such connecting rods extending from them to join structural steel to support ISES HRSG. The connecting rods 207 may be metal beams or metal elements. For example, connecting rods 207 may be rigid steel beams or steel elements. The connecting rods 207 provide a rigid mount for structural steel, which prevents or at least substantially limits the expansion of the channel defining elements and the flanges of the ISES HRSG modules in the direction of the two sides from which the connecting rods extend. The other two sides of the first housing 100a that do not have connecting rods extending from them are not so limited that this simplifies the expansion of the first housing in the vicinity of these two unlimited sides of the ISES HRSG due to the thermal conditions tested within one or more of the 305 HRSG channels. The expansion of the ISES HRSG in these two directions still allows the ISES HRSG to maintain a vertical position by connecting the connecting rods 207 to the structural steel next to the other two sides of the ISES HRSG. Additionally, since all ISES HRSG elements have an almost identical coefficient of thermal expansion, all elements extend relatively in the direction of these unlimited sides, which can allow the ISES HRSG structure to expand due to the thermal regime of the gas passing through the ISES HRSG without cracking the ISES HRSG structure or distortion due to the expansion of elements with significantly different speeds due to the different thermal conditions that these elements can experience.

[0037] In the case of a configuration as a vertical ISES HRSG, expanding the unlimited sides of the ISES HRSG enables the bottom of the HRSG (for example, the bottom of the first ISES HRSG body 100a, which is closest to the ISES HRSG inlet 100b that receives the hottest gas) expand freely to a greater extent than the upper parts of the HRSG (which are closer to the outlet channel 100c). This can contribute to the increased structural integrity of the unlimited sides of the ISES HRSG, since complex expansion speed variations are easily satisfied without weakening the proper support for the lowest part of the ISES HRSG from the lesser expanded upper parts of the ISES HRSG.

[0038] Embodiments of the ISES HRSG may also have an inlet channel 100b configured to have one or more channels defined within a shell of a heating case using internal stiffeners. The inlet channel 100b may have a shell defined by several connected modules similar to module 400. The inlet channel 100b or inlet channel modules may also be considered ISES HRSG components. The inlet duct modules may have a design similar to the modules of the first housing 100a, but have a slightly different shape or geometry, or define channels of a different shape through which hot gas can pass. The inlet channel modules 100b may include inner flanges that connect to the upper ends of the channel defining elements, and inner flanges attached to the lower ends of the channel defining elements. Each inlet module can be connected to directly adjacent inlet channel modules to form a shell. For example, the upper inner flange of one module may be directly connected to the lower inner flange of a directly adjacent inlet duct module 100b. Each of the inner flanges may be a ring structure. The inlet end of the inlet channel may have a formed opening for receiving hot gas from one or more sources and an outlet end that is connected to the first housing 100a so that hot gas flows from the inlet channel 100b into one or more channels 305 of the first housing 100a. The internal stiffeners, inner flanges, and channeling elements for the inlet channel 100b or the intake channel modules can have almost the same coefficient of thermal expansion (for example, the thermal expansion coefficient of the channeling elements, inner flanges, and internal stiffeners can vary by +/- 10% or 5%).

[0039] Connecting rods, for example, rigid steel beams or other steel elements, may be connected to flanges and channel defining elements for the inlet channel 100b for attachment to structural steel, for example, structural steel supports to support the inlet channel 100b. It will be appreciated that such connecting rods can transfer loads to structural steel, similarly to connecting rods 207 explained in this document. The connecting rods can extend only from two directly adjacent sides of the inlet channel 100b, so that the other sides of the inlet channel 100b have a configuration in which expansion due to thermal conditions within the inlet channel 100b can occur exclusively or almost exclusively in the region of unlimited sides of the inlet channel 100b ( for example, the sides of the inlet channel, in the region of which the connecting rods 207 are not extended for connection to structural steel). Also, insulation can be placed between the outer part of the shell and the structural steel frame to help ensure efficient use of the heat of the heated gas passing through one or more channels defined within the shell of the heating body of the inlet channel 100b. Connecting rods extending from the intake duct modules can pass through such insulation to join structural steel.

[0040] Often, traditional HRSGs must be stopped for the first one to two years of operation so that cracking and structural distortion can be eliminated before restarting and using HRSG again. This contributes to significant costs and inconvenience for the HRSG operator. Embodiments of the ISES HRSG may be configured to prevent such cracks and distortions so that such stops during the first one or two years of operation can be excluded. Therefore, the ISES HRSG embodiments provide significant cost savings for plant operators by using one or more ISES HRSG embodiments. Additionally, the ISES HRSG embodiments are configured to take into account thermal stresses caused by the temperature difference of the gas passing through the ISES HRSG, so that the duty cycle of the ISES HRSG embodiment can be configured to have a duty cycle that is many times longer (e.g. at least 4-5 times longer) the working cycle of a traditional HRSG.

[0041] It should be appreciated that various changes may be made to the ISES HRSG embodiments to take into account various design criteria. For example, the size and shape of the channel defining elements and stiffening elements may be any number of suitable sizes and shapes. As another example, the size and shape of the casing of an ISES HRSG module or casing, which accommodates channels for gas to flow from the ISES HRSG inlet to the HRSG outlet, can be any number of sizes that can satisfy hot gases at any number of possible costs that may be taken by ISES HRSG from turbines or other units that emit hot gas. The outer surface of the ISES HRSG shell may have a configuration in which there are no stiffeners that are traditionally present on the outside of the traditional HRSG. For example, embodiments of the ISES HRSG may not include stiffeners or ribs on the outer surface of the ISES HRSG sheath that accommodates one or more channels through which the hot gas received through the ISES HRSG passes. As yet another example, the ISES HRSG may be configured in such a way that evaporators or other types of heat exchangers can be configured to pass through the shell or one or more channels of the ISES HRSG embodiment so that heat from the hot gas that can flow through ISES HRSG, is transmitted to the fluid. Water, for example, can be heated through such an evaporator to evaporate the water and convert the water to steam for use in another processing unit that can use the ISES HRSG embodiment. Heat exchangers can be attached to the ISES HRSG or maintained next to the ISES HRSG. As yet another example, it is contemplated that channel defining elements and stiffening elements and flanges can be used to form modules for forming the ISES HRSG inlet channel 100b, and that connecting rods can extend only from two sides of the inlet channel to connect to structural steel to support inlet 100b ISES HRSG.

[0042] Although the invention has been described with reference to various exemplary embodiments, those skilled in the art will understand that various changes may be made and equivalents may be used instead of its elements without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the ideas of the invention without departing from its scope of protection. Therefore, the invention should not be limited to the specific embodiment disclosed as the optimal mode contemplated for the practice of the invention, and the invention should include all embodiments falling within the scope of the appended claims.

Claims (39)

1. Steam generator-recuperator containing: a plurality of modules including a corresponding upper annular flange and a corresponding lower annular flange, each of the modules being connected to at least one other module for jointly defining a housing having a first side, a second side, a third side and a fourth side defining an inner part of the housing, and the outer part of the housing, the first side being located between the second and third sides, the second side is between the first and fourth sides, the third side is between the first and fourth sides, the fourth side is located between the second and third parties so that the first side faces the fourth side and the second side faces the third side, while the inner part of the housing limits at least one channel for the flow of heated gas along the axis of the heated gas flow, and each channel includes many channel elements that are spaced apart from each other along the axis of the heated gas flow to limit the gaps between them, while the channel elements extend from the first side to the fourth side inside the inner part of the first housing and are located at a distance from the second and third sides; and a plurality of stiffeners passing along the axis of the heated gas stream, each of the stiffeners being located on the first wall and fourth wall in the inner part of the housing and placed between two of the channel elements; while the stiffeners and channel elements have almost the same coefficient of thermal expansion; wherein the upper annular flange of each module is connected to the corresponding upper ends of the channel elements and the corresponding upper ends of the stiffeners, while the lower annular flange of each module can be attached to the corresponding lower ends of the channel elements and the corresponding lower ends of the stiffeners, and a plurality of connecting rods, each of the connecting rods being connected to at least one of the channel elements and one of the lower annular flange and the upper annular flange, while the connecting rods extend outside the first housing only on the first and second sides of the housing for attachment to the structural steel, and outside the first housing on the third and fourth sides of the housing connecting rods do not extend to connect to structural steel. 2. The steam generator-recuperator according to claim 1, in which the stiffeners are exclusively in the inner part of the first body, and in which the diagonal braces are not included in the first channel. 3. The steam generator-recuperator according to claim 1, comprising: an inlet for receiving gas; and exhaust channel, while the housing is located between the inlet channel and the exhaust channel. 4. The steam generator-recuperator according to claim 1, which is a vertical steam generator-recuperator, and the gas flow axis is a vertical axis, so that gas flows vertically through each channel, and the channel elements are metal structures, and the stiffeners are metal constructions. 5. The steam generator-recuperator according to claim 1, in which the coefficient of thermal expansion of the channel elements is identical to the coefficient of thermal expansion of the stiffeners; or in which the coefficient of thermal expansion of the channel elements is between 90% and 110% of the coefficient of thermal expansion of the stiffeners. 6. The steam generator-recuperator according to claim 1, in which the diagonal braces are not included in the specified at least one channel. 7. The steam generator-recuperator according to claim 1, comprising: inlet duct and an outlet channel, the housing being located between the inlet channel and the outlet channel. 8. The steam generator-recuperator according to claim 1, in which connecting rods extending only from the first and second sides of the first housing limit the expansion of the first and second sides of the first housing, so that the expansion of the first housing caused by thermal conditions, leads to the expansion of the first housing essentially through expansion of the third and fourth sides of the first building. 9. The steam generator-recuperator according to claim 1, in which the coefficient of thermal expansion of the channel elements is identical to the coefficient of thermal expansion of the stiffeners; or in which the coefficient of thermal expansion of the elements of the first channel is a value that is between 90% and 110% of the coefficient of thermal expansion of the stiffeners. 10. The steam generator-recuperator according to claim 1, wherein the plurality of modules are connected in such a way that the lowest module is connected to the inlet channel, and the uppermost module is connected to the exhaust channel of the steam generator-recuperator. 11. The steam generator-recuperator according to claim 10, in which the uppermost module has an upper flange that is attached to the upper support, which is connected to the steel beams of an adjacent supporting structure. 12. The steam generator-recuperator according to claim 11, in which the adjacent support structure defines an outer casing for the steam generator-recuperator. 13. A vertical steam recuperator comprising: a shell having an outer part including a top and a bottom opposite the top, the top defining a top hole and the bottom defining a bottom hole, while the outer part also has a first side, a second side, a third side and a fourth side, the first side extending from above down and is placed between the second side and the third side, the second side is stretched from top to bottom and placed between the first side and the fourth side, the third side is stretched from top to bottom and is placed between the first side and the fourth side, the fourth side extends from top to bottom and is placed between the second side and the third side so that the fourth side faces the first side and the second side faces the third side, with the first side, second side, third side and fourth side jointly define the channel defined within the shell for the passage of heated gas through at least one channel along the axis of the gas flow extending from the bottom of the shell to the top of the shell, a plurality of channel elements that are spaced apart from each other along the axis of the heated gas flow to limit the gaps between them, while the channel elements extend from the first side to the fourth side inside the channel and are located at a distance from the second and third sides; a plurality of internal stiffeners located within the shell, each of the internal stiffeners being elongated along the axis of the heated gas stream and placed in the inner part of the housing between two of the channel elements; while the internal stiffeners and channel elements have almost the same coefficient of thermal expansion, and a plurality of connecting rods, each of the connecting rods being connected to and extending from one of the channel elements for passing from one of the first side of the shell and the second side of the shell for connecting to structural steel near the first and second sides of the shell, however, the connecting rods extend only from the first and second sides of the shell, so that the expansion of the shell caused by thermal conditions within the shell leads to the expansion of the shell through essentially the expansion of the third and fourth sides of the shell. 14. The steam generator-recuperator according to claim 13, in which the connecting rods are configured to attach to structural steel near the first and second sides of the shell, so that the expansion of the shell caused by thermal conditions within the shell leads only to the expansion of the third and fourth sides shells; and wherein the coefficient of thermal expansion of the channel setting elements is a value that is between 90% and 110% of the coefficient of thermal expansion of the internal stiffeners. 15. The steam generator-recuperator according to claim 13, containing: a plurality of inner flanges, each of the inner flanges extending around all of said at least one channel defined by channel defining elements, wherein each of the inner flanges is attached to a plurality of channel defining elements, a plurality of internal stiffening elements and a plurality of connecting rods; and wherein each of the connecting rods is attached to at least two of the channel defining elements next to the place where this connecting rod is attached to at least two of the channel defining elements. 16. The steam generator-recuperator according to claim 15, in which each of the inner flanges contains: oblong plates interconnected to define an annular structure, the flanges being made of a material having a coefficient of thermal expansion, which is almost the same as the coefficient of thermal expansion of channel setting elements.

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